CN110762540A - Combustion decision method and automatic combustion control method and system for garbage incinerator - Google Patents

Combustion decision method and automatic combustion control method and system for garbage incinerator Download PDF

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CN110762540A
CN110762540A CN201911005207.7A CN201911005207A CN110762540A CN 110762540 A CN110762540 A CN 110762540A CN 201911005207 A CN201911005207 A CN 201911005207A CN 110762540 A CN110762540 A CN 110762540A
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garbage incinerator
combustion
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variables
incinerator
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马晓茜
贺菡琰
余昭胜
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South China University of Technology SCUT
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23GCREMATION FURNACES; CONSUMING WASTE PRODUCTS BY COMBUSTION
    • F23G5/00Incineration of waste; Incinerator constructions; Details, accessories or control therefor
    • F23G5/50Control or safety arrangements
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
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    • G06F18/241Classification techniques relating to the classification model, e.g. parametric or non-parametric approaches
    • G06F18/2411Classification techniques relating to the classification model, e.g. parametric or non-parametric approaches based on the proximity to a decision surface, e.g. support vector machines
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06NCOMPUTING ARRANGEMENTS BASED ON SPECIFIC COMPUTATIONAL MODELS
    • G06N20/00Machine learning
    • G06N20/10Machine learning using kernel methods, e.g. support vector machines [SVM]

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Abstract

The invention discloses a combustion decision method and an automatic combustion control method and system of a garbage incinerator, wherein the combustion decision method comprises the steps of obtaining historical data of a target garbage incinerator and other garbage incinerators under normal operation and abnormal operation conditions, and obtaining an effective data sample according to the historical data; constructing a support vector machine by using the effective data samples, and obtaining a combustion decision model by using the support vector machine; acquiring current data of the target garbage incinerator, judging whether the target garbage incinerator needs to be adjusted or not according to the current data, and inputting the current data into a combustion decision model under the condition that the current data needs to be adjusted to obtain a combustion decision for adjusting the target garbage incinerator. The invention can generate a corresponding combustion decision according to the data of the garbage incinerator, realize automatic combustion control on the garbage incinerator through the combustion decision, and improve the abrasion and corrosion conditions of the garbage incinerator during combustion.

Description

Combustion decision method and automatic combustion control method and system for garbage incinerator
Technical Field
The invention relates to the technical field of garbage incinerators, in particular to a combustion decision method, an automatic combustion control method and an automatic combustion control system of a garbage incinerator.
Background
With the acceleration of the urbanization process in China, the urban domestic garbage is increasing day by day. Because the garbage incineration has the advantages of small occupied area, low influence degree on the surrounding environment and the like, the garbage incineration gradually becomes a mainstream mode of harmless treatment of urban garbage. As the domestic garbage is used as fuel, the domestic garbage has the characteristics of high water content, low-level heat productivity, large component change and the like, and the special combustion working condition of the domestic garbage is very easy to cause the abrasion and corrosion of the metal heating surface in the furnace. The reason is mainly as follows:
(1) in the process of burning the garbage in the furnace, chloride, alkali metal, pyrosulfate with higher concentration, and a mixture of heavy metal and low melting point which are related to corrosion are decomposed, and under the condition that the temperature of flue gas and the wall of the metal pipe is higher, high-temperature corrosion is generated on the metal heating surface. (2) The flue gas generated by combustion contains various acidic gases, salt substances and fly ash particles, and the substances are usually deposited on the wall of a metal pipe bearing high temperature and high pressure along with the flow of the flue gas, so that the scouring abrasion and the corrosion abrasion of the metal pipe wall on a heating surface are caused. (3) In order to effectively prevent the corrosion of the heated surface during the incineration of the garbage, the surface is usually protected from corrosion by coating with an anticorrosive material. However, due to the uncertainty of garbage components, the combustion temperature and working medium parameters of the garbage incineration boiler fluctuate in a large range, the fatigue of metal on a heating surface is accelerated, fatigue cracks are generated, external corrosive gas erodes crack gaps, and the corrosion of pipe walls is accelerated.
Therefore, it is necessary to develop a technology for controlling the automatic combustion of the waste incinerator in view of the degree of wear and corrosion occurring in the combustion of the waste incinerator.
Disclosure of Invention
A first object of the present invention is to overcome the disadvantages and drawbacks of the prior art and to provide a combustion decision method for a garbage incinerator, which can generate a combustion decision for controlling the combustion of the garbage incinerator according to data of the garbage incinerator.
The second objective of the present invention is to provide an automatic combustion control method for a garbage incinerator, which can realize automatic combustion control for the garbage incinerator according to the generated combustion decision, and improve the wear and corrosion conditions of the garbage incinerator during combustion.
A third object of the present invention is to provide an automatic combustion control system for a garbage incinerator, which can adjust the garbage incinerator according to a combustion decision generated by a controller of the garbage incinerator, so as to realize automatic combustion control of the garbage incinerator.
A fourth object of the present invention is to provide a storage medium.
It is a fifth object of the invention to provide a computing device.
The first purpose of the invention is realized by the following technical scheme: a combustion decision method of a garbage incinerator comprises the following steps:
s1, acquiring historical data of the target garbage incinerator and other garbage incinerators under normal operation and abnormal operation conditions, and obtaining effective data samples according to the historical data;
s2, constructing a support vector machine by using the effective data samples, and obtaining a combustion decision model by using the support vector machine;
s3, acquiring the current data of the target garbage incinerator in real time, judging whether the target garbage incinerator needs to be adjusted according to the current data,
and if so, inputting the current data into the combustion decision model to obtain a combustion decision for adjusting the target garbage incinerator.
Preferably, the normal operation specifically includes: the garbage incinerator does not break down, the combustion efficiency and the outlet temperature meet the requirements, and the pollutant discharge is in an index range;
the abnormal operation specifically comprises the following steps: the waste incinerator is out of order, the combustion efficiency and the outlet temperature do not meet the requirements or the pollutant discharge exceeds the index range;
the data of the waste incinerator includes condition variables, control variables and other variables, among them,
the condition variables comprise garbage moisture and heat value;
the control variables comprise primary air quantity and air speed, secondary air quantity and air speed, grate speed, all-level proportion of primary air and secondary air opening angle and opening degree;
other variables include horizontal flue outlet flue temperature, nitrogen oxide concentration, carbon monoxide concentration, sulfur oxide concentration, and hydrogen chloride concentration.
Further, in step S1, a valid data sample is obtained according to the history data, which is as follows:
constructing an original database by using historical data of other garbage incinerators under normal operation and abnormal operation conditions;
obtaining critical values of other variables according to historical data of the target garbage incinerator under normal operation and abnormal operation conditions;
and selecting historical data with the correlation of the condition variable larger than a correlation threshold value from the original database, and taking the selected historical data as valid data samples.
Further, in step S2, a support vector machine is constructed by using the valid data samples, and the combustion decision model is obtained by the support vector machine, which is as follows:
for m effective data samples, extracting a control variable and other variables from each effective data sample, and forming an individual feature vector by the control variable and the other variables to obtain m individual feature vectors;
generating n support vector machines by using One-overturs-rest SVM classification algorithm, and obtaining a combustion decision model by the support vector machines, wherein the method specifically comprises the following steps:
randomly dividing m individual feature vectors into k subsets which are equal in size and mutually exclusive, taking one subset as a test set, and taking the residual k-1 subsets as a sample set;
in the sample set, one individual feature vector and other similar individual feature vectors are classified into the same category, and the remaining individual feature vectors are obtained simultaneously;
in the remaining individual feature vectors, one of the individual feature vectors and other individual feature vectors similar to the one are classified into the same category, and the remaining individual feature vectors are updated;
repeating the classification process for the updated remaining individual feature vectors until the classification of all the individual feature vectors is completed, thereby generating n classes s1, s2 … sn;
sequentially classifying the individual feature vectors of any one category into one category, and classifying the rest other samples into another category to obtain n training sets, wherein the specific steps are as follows:
the vector corresponding to s1 is a positive set, and the vectors corresponding to s2 and s3 … sn are negative sets;
the vector corresponding to s2 is a positive set, and the vectors corresponding to s1 and s3 … sn are negative sets;
the vector corresponding to s3 is a positive set, and the vectors corresponding to s1 and s2 … sn are negative sets;
……
the vectors corresponding to sn are positive sets, and the vectors corresponding to s1 and s2 … sn-1 are negative sets;
the vector corresponding to the category is specifically composed of all individual feature vectors in each category;
taking n training sets as input, and respectively training to obtain n support vector machines; forming a combustion decision model by the obtained n support vector machines;
respectively inputting the test set into n support vector machines, and taking the maximum value of the result output by the support vector machines as the test result of the combustion decision model;
and taking one of the k subsets as a test set in turn, verifying the combustion decision model by a cross verification method, wherein the combustion decision model after verification is the final combustion decision model.
Furthermore, current data of the target garbage incinerator is obtained, specifically other current variables of the target garbage incinerator are detected;
judging whether the target garbage incinerator needs to be adjusted according to the current data, and specifically:
for the current other variables, judging whether the deviation between the current other variables and the critical values of the other variables is larger than a deviation threshold value,
if so, judging that the target garbage incinerator needs to be adjusted;
if not, the target garbage incinerator is judged not to need to be adjusted.
The second purpose of the invention is realized by the following technical scheme: an automatic combustion control method of a garbage incinerator comprises the following steps:
s1, acquiring historical data of the target garbage incinerator and other garbage incinerators under normal operation and abnormal operation conditions, and obtaining effective data samples according to the historical data;
s2, constructing a support vector machine by using the effective data samples, and obtaining a combustion decision model by using the support vector machine;
s3, acquiring the current data of the target garbage incinerator in real time, judging whether the target garbage incinerator needs to be adjusted according to the current data,
if so, inputting the current data into a combustion decision model to obtain a combustion decision for adjusting the target garbage incinerator;
and S4, adjusting the control variable of the target garbage incinerator according to the obtained combustion decision.
The third purpose of the invention is realized by the following technical scheme: an automatic combustion control system of a garbage incinerator, comprising: a garbage incinerator controller, a composite regulator and a data collector, wherein the garbage incinerator controller is connected with the composite regulator and the data collector,
the garbage incinerator controller is used for realizing the combustion decision method of the garbage incinerator, and outputting the combustion decision of the garbage incinerator;
the composite regulator comprises an actuator and a feedforward regulator, the actuator is connected with the feedforward regulator, and the actuator is used for executing combustion decision output by the garbage incinerator controller to regulate the garbage incinerator;
the feedforward regulator is used for feeding back the interference variable of the garbage incinerator to the actuator and carrying out feedforward compensation on the control variable;
the input end of the data collector is connected with the output end of the composite regulator, and the output end of the data collector is connected with the input end of the garbage incinerator controller and used for collecting other current variables of the target garbage incinerator in real time and feeding the other current variables back to the garbage incinerator controller.
Preferably, the actuator comprises a primary air actuator, a secondary air actuator and a fire grate actuator, the primary air actuator, the secondary air actuator and the fire grate actuator are all connected with the garbage incinerator controller, and the primary air actuator is used for adjusting the primary air quantity and the air speed of the garbage incinerator and the proportion of each level of the primary air; the secondary air actuator is used for adjusting the secondary air quantity and the air speed of the garbage incinerator and the angle and the opening degree of a secondary air port; the grate actuator is used for adjusting the grate speed.
The fourth purpose of the invention is realized by the following technical scheme: a storage medium stores a program that, when executed by a processor, implements a combustion decision method for a waste incinerator according to a first object of the present invention.
The fifth purpose of the invention is realized by the following technical scheme: a computing device comprising a processor and a memory for storing a processor executable program, the processor implementing a method for combustion decision-making in a waste incinerator according to the first object of the invention when executing the program stored in the memory.
Compared with the prior art, the invention has the following advantages and effects:
(1) the invention relates to a combustion decision method of a garbage incinerator, which comprises the steps of firstly obtaining historical data of a target garbage incinerator and other garbage incinerators under normal operation and abnormal operation conditions, and obtaining effective data samples according to the historical data; constructing a support vector machine by using the effective data samples, and obtaining a combustion decision model by using the support vector machine; acquiring current data of the target garbage incinerator, judging whether the target garbage incinerator needs to be adjusted or not according to the current data, and inputting the current data into a combustion decision model under the condition that the current data needs to be adjusted to obtain a combustion decision for adjusting the target garbage incinerator. The invention generates the combustion decision of the garbage incinerator based on the data of the garbage incinerator and a machine learning algorithm, thereby providing an auxiliary decision and a guidance suggestion for the high-efficiency low-pollution combustion and the anti-abrasion and anti-corrosion operation optimization of the garbage incinerator.
(2) According to the automatic combustion control method of the garbage incinerator, the garbage incinerator is adjusted by monitoring the data of the garbage incinerator in real time and generating a corresponding combustion decision, so that the automatic combustion control of the garbage incinerator is realized, and the garbage incinerator can run more finely and automatically.
(3) The automatic combustion control system of the garbage incinerator comprises a garbage incinerator controller, a composite regulator and a data collector, current other variables of a target garbage incinerator are collected in real time through the data collector, and the current other variables are fed back to the garbage incinerator controller, so that the problem that the combustion process of the garbage incinerator is a large time lag process and is difficult to react according to direct parameters to obtain good control is avoided, the garbage incinerator controller can quickly output an accurate combustion decision, and the automatic combustion of the garbage incinerator is accurately controlled; the composite regulator can feed back the interference variable of the garbage incinerator to the actuator by arranging the feedforward regulator, performs feedforward compensation on the control variable, counteracts the influence of the interference variable on the garbage incinerator, and improves the applicability and accuracy of combustion decision.
Drawings
FIG. 1 is a flow chart of a combustion decision method of a garbage incinerator according to the present invention.
FIG. 2 is a flow chart of an automatic combustion control method of the garbage incinerator according to the present invention.
Fig. 3 is a schematic block diagram of an automatic combustion control system of the garbage incinerator of the present invention.
FIG. 4 is a schematic view of the connection of the automatic combustion control system of the present invention to a garbage incinerator.
Detailed Description
The present invention will be described in further detail with reference to examples and drawings, but the present invention is not limited thereto.
Example 1
The embodiment discloses a combustion decision method of a garbage incinerator, as shown in fig. 1, comprising the following steps:
and S1, acquiring historical data of the target garbage incinerator and other garbage incinerators under normal operation and abnormal operation conditions, and obtaining effective data samples according to the historical data.
Wherein, the normal operation specifically is: the garbage incinerator does not break down, the combustion efficiency and the outlet temperature meet the requirements, and the pollutant discharge is in an index range;
the abnormal operation specifically comprises the following steps: the waste incinerator is out of order, the combustion efficiency and the outlet temperature do not meet the requirements or the pollutant discharge exceeds the index range.
Since different garbage incinerators and garbage have different normal operation judgment standards, whether the garbage incinerator operates normally or not needs to be judged according to actual conditions.
In the present embodiment, the history data of the target garbage incinerator and other garbage incinerators specifically refers to data in a certain time range in the recent past, the data including condition variables, control variables, and other variables, wherein,
the condition variables comprise garbage moisture and garbage heat value;
the control variables comprise primary air quantity and air speed, secondary air quantity and air speed, grate speed, all-level proportion of primary air and secondary air opening angle and opening degree;
other variables include horizontal stack outlet flue temperature, nitrogen oxide concentration, carbon monoxide concentration, sulfur oxide concentration, and hydrogen chloride concentration.
Obtaining effective data samples according to historical data, which is as follows:
and (4) constructing to obtain an original database by using historical data of other garbage incinerators under normal operation and abnormal operation conditions.
And obtaining critical values of other variables according to historical data of the target garbage incinerator under normal operation and abnormal operation conditions. In this embodiment, the historical data is analyzed for big data, and the data mining algorithm is used to calculate the critical values of other variables.
And selecting historical data with the correlation of the condition variable larger than a correlation threshold value from the original database, and taking the selected historical data as valid data samples. In this embodiment, since the condition variables generated by different garbage incinerators and garbage are different, the correlation threshold of the condition variables needs to be set according to actual requirements.
S2, constructing a support vector machine by using the effective data samples, and obtaining a combustion decision model by the support vector machine, wherein the method specifically comprises the following steps:
for m effective data samples, extracting a control variable and other variables from each effective data sample, and forming an individual feature vector by the control variable and the other variables to obtain m individual feature vectors;
generating n support vector machines by using One-overturs-rest SVM classification algorithm, and obtaining a combustion decision model by the support vector machines, wherein the method specifically comprises the following steps:
(1) randomly dividing m individual feature vectors into k subsets which are equal in size and mutually exclusive, taking one subset as a test set, and taking the residual k-1 subsets as a sample set;
(2) in the sample set, one individual feature vector and other similar individual feature vectors are classified into the same category, and the remaining individual feature vectors are obtained simultaneously;
in the remaining individual feature vectors, one of the individual feature vectors and other individual feature vectors similar to the one are classified into the same category, and the remaining individual feature vectors are updated;
repeating the classification process for the updated remaining individual feature vectors until the classification of all the individual feature vectors is completed, thereby generating n classes s1, s2 … sn;
(3) sequentially classifying the individual feature vectors of any one category into one category, and classifying the rest other samples into another category to obtain n training sets, wherein the specific steps are as follows:
the vector corresponding to s1 is a positive set, and the vectors corresponding to s2 and s3 … sn are negative sets;
the vector corresponding to s2 is a positive set, and the vectors corresponding to s1 and s3 … sn are negative sets;
the vector corresponding to s3 is a positive set, and the vectors corresponding to s1 and s2 … sn are negative sets;
……
the vectors corresponding to sn are positive sets, and the vectors corresponding to s1 and s2 … sn-1 are negative sets;
the vector corresponding to the category is specifically composed of all individual feature vectors in each category;
(4) taking n training sets as input, and respectively training to obtain n support vector machines; forming a combustion decision model by the obtained n support vector machines;
(5) respectively inputting the test set into n support vector machines, and taking the maximum value of the result output by the support vector machines as the test result of the combustion decision model;
(6) and taking one of the k subsets as a test set in turn, verifying the combustion decision model by a cross verification method, wherein the combustion decision model after verification is the final combustion decision model.
S3, acquiring the current data of the target garbage incinerator in real time, judging whether the target garbage incinerator needs to be adjusted according to the current data,
if so, inputting the current data into a combustion decision model to obtain a combustion decision for adjusting the target garbage incinerator;
the method comprises the steps of obtaining current data of a target garbage incinerator, specifically detecting current other variables of the target garbage incinerator, namely smoke temperature at an outlet of a horizontal flue, nitrogen oxide concentration, carbon monoxide concentration, sulfur oxide concentration and hydrogen chloride concentration.
Judging whether the target garbage incinerator needs to be adjusted, and specifically: for the current other variables, judging whether the deviation between the current other variables and the critical values of the other variables is larger than a deviation threshold value,
if so, judging that the target garbage incinerator needs to be adjusted;
if not, the target garbage incinerator is judged not to need to be adjusted.
In this embodiment, since different garbage incinerators and garbage may generate different other variables, the deviation threshold needs to be set according to actual requirements.
The embodiment also discloses an automatic combustion control method of a garbage incinerator, as shown in fig. 2, comprising the combustion decision method as described above, specifically as follows:
s1, acquiring historical data of the target garbage incinerator and other garbage incinerators under normal operation and abnormal operation conditions, and obtaining effective data samples according to the historical data;
s2, constructing a support vector machine by using the effective data samples, and obtaining a combustion decision model by using the support vector machine;
s3, acquiring the current data of the target garbage incinerator in real time, judging whether the target garbage incinerator needs to be adjusted according to the current data,
if so, inputting the current data into a combustion decision model to obtain a combustion decision for adjusting the target garbage incinerator;
and S4, adjusting the control variable of the target garbage incinerator according to the obtained combustion decision, namely adjusting the primary air quantity and the air speed, the primary air ratio of each level, the secondary air quantity and the air speed, the secondary air opening angle and the opening degree and the grate speed of the garbage incinerator, so as to realize the automatic combustion control of the garbage incinerator.
Example 2
The embodiment discloses an automatic combustion control system of a garbage incinerator, as shown in fig. 3 and 4, comprising: a garbage incinerator controller, a composite regulator and a data collector, wherein the garbage incinerator controller is connected with the composite regulator and the data collector,
the garbage incinerator controller is used for implementing the combustion decision method of the garbage incinerator as described in embodiment 1 above, and outputting the combustion decision of the garbage incinerator as follows:
s1, acquiring historical data of the target garbage incinerator and other garbage incinerators under normal operation and abnormal operation conditions, and obtaining effective data samples according to the historical data;
s2, constructing a support vector machine by using the effective data samples, and obtaining a combustion decision model by using the support vector machine;
s3, acquiring the current data of the target garbage incinerator in real time, judging whether the target garbage incinerator needs to be adjusted according to the current data,
and if so, inputting the current data into the combustion decision model to obtain a combustion decision for adjusting the target garbage incinerator.
The composite regulator comprises an actuator and a feedforward regulator, the actuator and the feedforward regulator are connected and are both connected with a garbage incinerator controller, wherein,
the actuator is used for executing the combustion decision output by the garbage incinerator controller and adjusting the garbage incinerator. As shown in fig. 4, the actuator comprises a primary air actuator, a secondary air actuator and a grate actuator, the primary air actuator, the secondary air actuator and the grate actuator are all connected with the garbage incinerator controller, wherein the primary air actuator is used for adjusting the primary air quantity and the air speed of the garbage incinerator and the proportion of each level of the primary air; the secondary air actuator is used for adjusting the secondary air quantity and the air speed of the garbage incinerator and the angle and the opening degree of a secondary air port; the grate actuator is used for adjusting the grate speed.
The input end of the feedforward regulator inputs the interference variable of the garbage incinerator, and the output end of the feedforward regulator is connected with the actuator and used for feeding the interference variable of the garbage incinerator back to the actuator to perform feedforward compensation on the control variable, so that the effect of offsetting the influence of the interference variable on the garbage incinerator is achieved. The disturbance variable of the garbage incinerator can be factors which possibly influence the combustion process, such as the characteristics of garbage, the air excess coefficient, the turbulent residence time of smoke, the external environment of the garbage incinerator and the like.
The output of compound regulator is connected to data collection station's input, the input of msw incineration furnace controller is connected to data collection station's output, be used for gather target msw incineration furnace's current other variables in real time, give back to msw incineration furnace controller with current other variables, avoid hardly obtaining good control according to direct parameter reaction because the combustion process of msw incineration furnace is the big time lag process, make the msw incineration furnace controller can finely tune current other variables that the feedback obtained according to other predetermined variable given values, output more accurate and accord with actual conditions's combustion decision fast, the realization carries out more accurate control to the automatic combustion of msw incineration furnace.
The functional block diagram of the automatic combustion control system can be specifically seen in fig. 3, wherein the input specifically refers to preset reference values, such as other variable set values, correlation threshold values, and deviation threshold values; the output refers to other variables of the regulated garbage incinerator during combustion, and specifically refers to the smoke temperature at the outlet of the horizontal flue, the concentration of nitrogen oxides, the concentration of carbon monoxide, the concentration of sulfur oxides and the concentration of hydrogen chloride. As can be seen from fig. 3, the garbage incinerator controller transmits the generated combustion decision to the actuator, the feedforward regulator transmits the disturbance variable to the actuator, the actuator executes the combustion decision while considering the influence of the disturbance variable, and thus more appropriately regulates the garbage incinerator, and the data collector feeds back other variables of the garbage incinerator collected in real time to the garbage incinerator controller, so that it can be seen that the whole automatic combustion process of the garbage incinerator is a dynamic and controllable process.
Example 3
The present embodiment discloses a storage medium storing a program, which when executed by a processor, implements the combustion decision method of the waste incinerator as described in embodiment 1 above, specifically as follows:
s1, acquiring historical data of the target garbage incinerator and other garbage incinerators under normal operation and abnormal operation conditions, and obtaining effective data samples according to the historical data;
s2, constructing a support vector machine by using the effective data samples, and obtaining a combustion decision model by using the support vector machine;
s3, acquiring the current data of the target garbage incinerator in real time, judging whether the target garbage incinerator needs to be adjusted according to the current data,
and if so, inputting the current data into the combustion decision model to obtain a combustion decision for adjusting the target garbage incinerator.
The storage medium in this embodiment may be a magnetic disk, an optical disk, a computer Memory, a Read-Only Memory (ROM), a Random Access Memory (RAM), a usb disk, a removable hard disk, or other media.
Example 4
The embodiment discloses a computing device, which comprises a processor and a memory for storing a processor executable program, wherein when the processor executes the program stored in the memory, the combustion decision method of the garbage incinerator as described in the above embodiment 1 is implemented, specifically as follows:
s1, acquiring historical data of the target garbage incinerator and other garbage incinerators under normal operation and abnormal operation conditions, and obtaining effective data samples according to the historical data;
s2, constructing a support vector machine by using the effective data samples, and obtaining a combustion decision model by using the support vector machine;
s3, acquiring the current data of the target garbage incinerator in real time, judging whether the target garbage incinerator needs to be adjusted according to the current data,
and if so, inputting the current data into the combustion decision model to obtain a combustion decision for adjusting the target garbage incinerator.
The computing device described in this embodiment may be a desktop computer, a notebook computer, a smart phone, a PDA handheld terminal, a tablet computer, or other terminal device with a processor function.
The above embodiments are preferred embodiments of the present invention, but the present invention is not limited to the above embodiments, and any other changes, modifications, substitutions, combinations, and simplifications which do not depart from the spirit and principle of the present invention should be construed as equivalents thereof, and all such changes, modifications, substitutions, combinations, and simplifications are intended to be included in the scope of the present invention.

Claims (10)

1. A combustion decision method of a garbage incinerator is characterized by comprising the following steps:
s1, acquiring historical data of the target garbage incinerator and other garbage incinerators under normal operation and abnormal operation conditions, and obtaining effective data samples according to the historical data;
s2, constructing a support vector machine by using the effective data samples, and obtaining a combustion decision model by using the support vector machine;
s3, acquiring the current data of the target garbage incinerator in real time, judging whether the target garbage incinerator needs to be adjusted according to the current data,
and if so, inputting the current data into the combustion decision model to obtain a combustion decision for adjusting the target garbage incinerator.
2. The combustion decision method of a garbage incinerator according to claim 1, characterized in that the normal operation is specifically: the garbage incinerator does not break down, the combustion efficiency and the outlet temperature meet the requirements, and the pollutant discharge is in an index range;
the abnormal operation specifically comprises the following steps: the waste incinerator is out of order, the combustion efficiency and the outlet temperature do not meet the requirements or the pollutant discharge exceeds the index range;
the data of the waste incinerator includes condition variables, control variables and other variables, among them,
the condition variables comprise garbage moisture and heat value;
the control variables comprise primary air quantity and air speed, secondary air quantity and air speed, grate speed, all-level proportion of primary air and secondary air opening angle and opening degree;
other variables include horizontal flue outlet flue temperature, nitrogen oxide concentration, carbon monoxide concentration, sulfur oxide concentration, and hydrogen chloride concentration.
3. The combustion decision method of a garbage incinerator according to claim 2, characterized in that in step S1, effective data samples are obtained according to historical data, specifically as follows:
constructing an original database by using historical data of other garbage incinerators under normal operation and abnormal operation conditions;
obtaining critical values of other variables according to historical data of the target garbage incinerator under normal operation and abnormal operation conditions;
and selecting historical data with the correlation of the condition variable larger than a correlation threshold value from the original database, and taking the selected historical data as valid data samples.
4. The combustion decision method of a garbage incinerator according to claim 3, characterized in that in step S2, effective data samples are used to construct support vector machine, and the support vector machine is used to obtain combustion decision model, specifically as follows:
for m effective data samples, extracting a control variable and other variables from each effective data sample, and forming an individual feature vector by the control variable and the other variables to obtain m individual feature vectors;
generating n support vector machines by using One-overturs-rest SVM classification algorithm, and obtaining a combustion decision model by the support vector machines, wherein the method specifically comprises the following steps:
randomly dividing m individual feature vectors into k subsets which are equal in size and mutually exclusive, taking one subset as a test set, and taking the residual k-1 subsets as a sample set;
in the sample set, one individual feature vector and other similar individual feature vectors are classified into the same category, and the remaining individual feature vectors are obtained simultaneously;
in the remaining individual feature vectors, one of the individual feature vectors and other individual feature vectors similar to the one are classified into the same category, and the remaining individual feature vectors are updated;
repeating the classification process for the updated remaining individual feature vectors until the classification of all the individual feature vectors is completed, thereby generating n classes s1, s2 … sn;
sequentially classifying the individual feature vectors of any one category into one category, and classifying the rest other samples into another category to obtain n training sets, wherein the specific steps are as follows:
the vector corresponding to s1 is a positive set, and the vectors corresponding to s2 and s3 … sn are negative sets;
the vector corresponding to s2 is a positive set, and the vectors corresponding to s1 and s3 … sn are negative sets;
the vector corresponding to s3 is a positive set, and the vectors corresponding to s1 and s2 … sn are negative sets;
……
the vectors corresponding to sn are positive sets, and the vectors corresponding to s1 and s2 … sn-1 are negative sets;
the vector corresponding to the category is specifically composed of all individual feature vectors in each category;
taking n training sets as input, and respectively training to obtain n support vector machines; forming a combustion decision model by the obtained n support vector machines;
respectively inputting the test set into n support vector machines, and taking the maximum value of the result output by the support vector machines as the test result of the combustion decision model;
and taking one of the k subsets as a test set in turn, verifying the combustion decision model by a cross verification method, wherein the combustion decision model after verification is the final combustion decision model.
5. The combustion decision method of a garbage incinerator according to claim 3, characterized in that, the current data of the target garbage incinerator is obtained, specifically, other current variables of the target garbage incinerator are detected;
judging whether the target garbage incinerator needs to be adjusted according to the current data, and specifically:
for the current other variables, judging whether the deviation between the current other variables and the critical values of the other variables is larger than a deviation threshold value,
if so, judging that the target garbage incinerator needs to be adjusted;
if not, the target garbage incinerator is judged not to need to be adjusted.
6. An automatic combustion control method of a garbage incinerator is characterized by comprising the following steps:
s1, acquiring historical data of the target garbage incinerator and other garbage incinerators under normal operation and abnormal operation conditions, and obtaining effective data samples according to the historical data;
s2, constructing a support vector machine by using the effective data samples, and obtaining a combustion decision model by using the support vector machine;
s3, acquiring the current data of the target garbage incinerator in real time, judging whether the target garbage incinerator needs to be adjusted according to the current data,
if so, inputting the current data into a combustion decision model to obtain a combustion decision for adjusting the target garbage incinerator;
and S4, adjusting the control variable of the target garbage incinerator according to the obtained combustion decision.
7. An automatic combustion control system of a garbage incinerator, comprising: a garbage incinerator controller, a composite regulator and a data collector, wherein the garbage incinerator controller is connected with the composite regulator and the data collector,
the garbage incinerator controller is used for realizing the combustion decision method of the garbage incinerator according to any one of claims 1 to 5 and outputting the combustion decision of the garbage incinerator;
the composite regulator comprises an actuator and a feedforward regulator, the actuator is connected with the feedforward regulator, and the actuator is used for executing combustion decision output by the garbage incinerator controller to regulate the garbage incinerator;
the feedforward regulator is used for feeding back the interference variable of the garbage incinerator to the actuator and carrying out feedforward compensation on the control variable;
the input end of the data collector is connected with the output end of the composite regulator, and the output end of the data collector is connected with the input end of the garbage incinerator controller and used for collecting other current variables of the target garbage incinerator in real time and feeding the other current variables back to the garbage incinerator controller.
8. The automatic combustion control system of the garbage incinerator according to claim 7, wherein the actuators comprise a primary air actuator, a secondary air actuator and a grate actuator, the primary air actuator, the secondary air actuator and the grate actuator are all connected with the garbage incinerator controller, and the primary air actuator is used for adjusting the primary air volume, the air speed and the primary air ratio of the garbage incinerator at each level; the secondary air actuator is used for adjusting the secondary air quantity and the air speed of the garbage incinerator and the angle and the opening degree of a secondary air port; the grate actuator is used for adjusting the grate speed.
9. A storage medium storing a program, wherein the program, when executed by a processor, implements a combustion decision method of a garbage incinerator according to any one of claims 1 to 5.
10. A computing device comprising a processor and a memory for storing a processor-executable program, wherein the processor, when executing the program stored in the memory, implements a method of combustion decision for a waste incinerator as claimed in any one of claims 1 to 5.
CN201911005207.7A 2019-10-22 2019-10-22 Combustion decision method and automatic combustion control method and system for garbage incinerator Pending CN110762540A (en)

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